Charge pump circuit

ABSTRACT

Provided is a charge pump circuit including: a first transistor; a second transistor to which a constant current is supplied; a third transistor connected to the first transistor and a voltage source; a fourth transistor group including N transistors arranged in a cascade on the first transistor side, the N transistors all including control terminals connected to the second transistor; a fifth transistor group including N transistors arranged in a cascade on the second transistor side, the N transistors all including control terminals connected to the second transistor; a first switch that connects the first transistor to the second transistor; a second switch that connects the first transistor to a ground node; a third switch that connects the third transistor to the fifth transistor group; and a fourth switch that connects the third transistor to the ground node.

TECHNICAL FIELD

The present technology relates to a charge pump circuit, andparticularly to a charge pump circuit enabled to reduce a circuit area.

BACKGROUND ART

In a Phase Locked Loop (PLL) circuit and the like, a charge pump circuitis used. As a configuration of the charge pump circuit, for example, agate switching type configuration is known (for example, see PatentDocument 1.).

CITATION LIST Patent Document

-   Patent Document 1: Japanese Patent Application Laid-Open No.    62-234415

SUMMARY OF THE INVENTION Problems to be Solved by the Invention

By the way, the gate switching type charge pump circuit can operate at alow voltage, but it is necessary to arrange a sufficiently largecapacitance to suppress a decrease in a current value, and a circuitarea increases. A technology for suppressing the increase in the circuitarea has therefore been required in the charge pump circuit.

The present technology has been made in view of such a situation, and itis intended to enable reduction of the circuit area.

Solutions to Problems

A charge pump circuit according to a first aspect of the presenttechnology is a charge pump circuit including: a first transistorincluding a first terminal, a second terminal connected to an outputterminal, and a control terminal; a second transistor including a firstterminal, a second terminal to which a constant current is supplied, anda control terminal connected to the second terminal; a third transistorincluding a first terminal connected to the first terminal of the firsttransistor, a second terminal connected to a voltage source thatsupplies an arbitrary voltage, and a control terminal; a fourthtransistor group including N transistors arranged in a cascade on afirst terminal side of the first transistor, where N is an integergreater than or equal to 1, the N transistors all including controlterminals connected to the control terminal of the second transistor; afifth transistor group including N transistors arranged in a cascade ona first terminal side of the second transistor, the N transistors allincluding control terminals connected to the control terminal of thesecond transistor; a first switch element that electrically connects thecontrol terminal of the first transistor to the control terminal of thesecond transistor; a second switch element that connects the controlterminal of the first transistor to a ground node; a third switchelement that electrically connects the control terminal of the thirdtransistor to the control terminals of the fourth transistor group andthe fifth transistor group; and a fourth switch element that connectsthe control terminal of the third transistor to the ground node, inwhich: the first transistor has a channel width and a channel lengthidentical to those of the second transistor; the third transistor hasthe channel width and the channel length identical to those of the firsttransistor and the second transistor; in the fourth transistor group,each of the transistors has the channel width and the channel lengthidentical to those of the second transistor, and a first terminal of oneof the transistors is connected to the ground node; and in the fifthtransistor group, each of the transistors has the channel width and thechannel length identical to those of the second transistor, and a firstterminal of one of the transistors is connected to the ground node.

A charge pump circuit according to a second aspect of the presenttechnology is a charge pump circuit including: a first transistorincluding a first terminal, a second terminal connected to an outputterminal, and a control terminal; a second transistor including a firstterminal, a second terminal to which a constant current is supplied, anda control terminal connected to the second terminal; a third transistorincluding a first terminal connected to the first terminal of the firsttransistor, a second terminal connected to a voltage source thatsupplies an arbitrary voltage, and a control terminal; a fourthtransistor group including N transistors arranged in a cascade on afirst terminal side of the first transistor, where N is an integergreater than or equal to 1, the N transistors all including controlterminals connected to the control terminal of the second transistor; afifth transistor group including N transistors arranged in a cascade ona first terminal side of the second transistor, the N transistors allincluding control terminals connected to the control terminal of thesecond transistor; a first switch element that electrically connects thecontrol terminal of the first transistor to the control terminal of thesecond transistor; a second switch element that connects the controlterminal of the first transistor to a power supply node; a third switchelement that electrically connects the control terminal of the thirdtransistor to the control terminals of the fourth transistor group andthe fifth transistor group; and a fourth switch element that connectsthe control terminal of the third transistor to the power supply node,in which: the first transistor has a channel width and a channel lengthidentical to those of the second transistor; the third transistor hasthe channel width and the channel length identical to those of the firsttransistor and the second transistor; in the fourth transistor group,each of the transistors has the channel width and the channel lengthidentical to those of the second transistor, and a first terminal of oneof the transistors is connected to the power supply node; and in thefifth transistor group, each of the transistors has the channel widthand the channel length identical to those of the second transistor, anda first terminal of one of the transistors is connected to the powersupply node.

A charge pump circuit according to a third aspect of the presenttechnology is a charge pump circuit including: a first transistorincluding a first terminal, a second terminal connected to an outputterminal, and a control terminal; a second transistor including a firstterminal, a second terminal to which a first constant current issupplied, and a control terminal connected to the second terminal; athird transistor including a first terminal connected to the firstterminal of the first transistor, a second terminal connected to a firstvoltage source that supplies a first voltage, and a control terminal; afourth transistor group including N transistors arranged in a cascade ona first terminal side of the first transistor, where N is an integergreater than or equal to 1, the N transistors all including controlterminals connected to the control terminal of the second transistor; afifth transistor group including N transistors arranged in a cascade ona first terminal side of the second transistor, the N transistors allincluding control terminals connected to the control terminal of thesecond transistor; a first switch element that electrically connects thecontrol terminal of the first transistor to the control terminal of thesecond transistor; a second switch element that connects the controlterminal of the first transistor to a ground node; a third switchelement that electrically connects the control terminal of the thirdtransistor to the control terminals of the fourth transistor group andthe fifth transistor group; a fourth switch element that connects thecontrol terminal of the third transistor to the ground node; a sixthtransistor including a first terminal, a second terminal connected tothe output terminal, and a control terminal; a seventh transistorincluding a first terminal, a second terminal to which a second constantcurrent is supplied, and a control terminal connected to the secondterminal; an eighth transistor including a first terminal connected tothe first terminal of the sixth transistor, a second terminal connectedto a second voltage source that supplies a second voltage, and a controlterminal; a ninth transistor group including M transistors arranged in acascade on a first terminal side of the sixth transistor, where M is aninteger greater than or equal to 1, the M transistors all includingcontrol terminals connected to the control terminal of the seventhtransistor; a tenth transistor group including M transistors arranged ina cascade on a first terminal side of the seventh transistor, the Mtransistors all including control terminals connected to the controlterminal of the seventh transistor; a fifth switch element thatelectrically connects the control terminal of the sixth transistor tothe control terminal of the seventh transistor; a sixth switch elementthat connects the control terminal of the sixth transistor to a powersupply node; a seventh switch element that electrically connects thecontrol terminal of the eighth transistor to the control terminals ofthe ninth transistor group and the tenth transistor group; and an eighthswitch element that connects the control terminal of the eighthtransistor to the power supply node, in which: the first transistor hasa channel width and a channel length identical to those of the secondtransistor; the third transistor has the channel width and the channellength identical to those of the first transistor and the secondtransistor; in the fourth transistor group, each of the transistors hasthe channel width and the channel length identical to those of thesecond transistor, and a first terminal of one of the transistors isconnected to the ground node; in the fifth transistor group, each of thetransistors has the channel width and the channel length identical tothose of the second transistor, and a first terminal of one of thetransistors is connected to the ground node; the sixth transistor has achannel width and a channel length identical to those of the seventhtransistor; the eighth transistor has the channel width and the channellength identical to those of the sixth transistor and the seventhtransistor; in the ninth transistor group, each of the transistors hasthe channel width and the channel length identical to those of theseventh transistor, and a first terminal of one of the transistors isconnected to the power supply node; and in the tenth transistor group,each of the transistors has the channel width and the channel lengthidentical to those of the seventh transistor, and a first terminal ofone of the transistors is connected to the power supply node.

A charge pump circuit according to a fourth aspect of the presenttechnology is a charge pump circuit including: a current sourcetransistor including a first terminal connected to a ground node, asecond terminal connected to an output terminal, and a control terminal;a first switch element that connects the control terminal of the currentsource transistor to a first signal line to which a first voltage isapplied; a second switch element that connects the control terminal ofthe current source transistor to the ground node; a capacitance elementincluding one electrode connected to the first signal line, and anotherelectrode connectable to a second signal line to which a second voltageis applied or a third signal line to which a difference voltage betweenthe second voltage and the first voltage is applied; a third switchelement that connects the other electrode of the capacitance element tothe third signal line; and a fourth switch element that connects theother electrode of the capacitance element to the second signal line.

A charge pump circuit according to a fifth aspect of the presenttechnology is a charge pump circuit including: a current sourcetransistor including a first terminal connected to a power supply node,a second terminal connected to an output terminal, and a controlterminal; a first switch element that connects the control terminal ofthe current source transistor to a first signal line to which adifference voltage between a power supply voltage and a first voltage isapplied; a second switch element that connects the control terminal ofthe current source transistor to the power supply node; a capacitanceelement including one electrode connected to the first signal line, andanother electrode connectable to a second signal line to which a secondvoltage is applied or a third signal line to which a sum voltage of thesecond voltage and the first voltage is applied; a third switch elementthat connects the other electrode of the capacitance element to thethird signal line; and a fourth switch element that connects the otherelectrode of the capacitance element to the second signal line.

A charge pump circuit according to a sixth aspect of the presenttechnology is a charge pump circuit including: a first transistorincluding a first terminal connected to a ground node, a second terminalconnected to an output terminal, and a control terminal; a first switchelement that connects the control terminal of the first transistor to afirst signal line to which a first voltage is applied; a second switchelement that connects the control terminal of the first transistor tothe ground node; a first capacitance element including one electrodeconnected to the first signal line, and another electrode connectable toa second signal line to which a second voltage is applied or a thirdsignal line to which a difference voltage between the second voltage andthe first voltage is applied; a third switch element that connects theother electrode of the first capacitance element to the third signalline; a fourth switch element that connects the other electrode of thefirst capacitance element to the second signal line; a second transistorincluding a first terminal connected to a power supply node, a secondterminal connected to the output terminal, and a control terminal; afifth switch element that connects the control terminal of the secondtransistor to a fourth signal line to which a difference voltage betweena power supply voltage and a third voltage is applied; a sixth switchelement that connects the control terminal of the second transistor tothe power supply node; a second capacitance element including oneelectrode connected to the fourth signal line, and another electrodeconnectable to a fifth signal line to which a fourth voltage is appliedor a sixth signal line to which a sum voltage of the fourth voltage andthe third voltage is applied; a seventh switch element that connects theother electrode of the second capacitance element to the sixth signalline; and an eighth switch element that connects the other electrode ofthe second capacitance element to the fifth signal line.

Note that, the charge pump circuits according to the first to sixthaspects of the present technology may be independent devices, or may beinternal blocks that constitute one device.

Effects of the Invention

According to the first to sixth aspects of the present technology, thecircuit area can be reduced.

Note that, the effect described here is not necessarily limited, and canbe any effect described in the present disclosure.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a circuit diagram illustrating an example of a firstconfiguration of a charge pump circuit according to a first embodiment.

FIG. 2 is a timing chart illustrating operation of switches in theexample of the first configuration of the charge pump circuit accordingto the first embodiment.

FIG. 3 is a circuit diagram illustrating an example of a secondconfiguration of the charge pump circuit according to the firstembodiment.

FIG. 4 is a timing chart illustrating operation of switches of theexample of the second configuration of the charge pump circuit accordingto the first embodiment.

FIG. 5 is a circuit diagram illustrating an example of a thirdconfiguration of the charge pump circuit according to the firstembodiment.

FIG. 6 is a timing chart illustrating operation of switches of theexample of the third configuration of the charge pump circuit accordingto the first embodiment.

FIG. 7 is a circuit diagram illustrating an example of a firstconfiguration of a charge pump circuit according to a second embodiment.

FIG. 8 is a timing chart illustrating operation of switches in theexample of the first configuration of the charge pump circuit accordingto the second embodiment.

FIG. 9 is a circuit diagram illustrating an example of a secondconfiguration of the charge pump circuit according to the secondembodiment.

FIG. 10 is a timing chart illustrating operation of switches of theexample of the second configuration of the charge pump circuit accordingto the second embodiment.

FIG. 11 is a circuit diagram illustrating an example of a thirdconfiguration of the charge pump circuit according to the secondembodiment.

FIG. 12 is a timing chart illustrating operation of switches of theexample of the third configuration of the charge pump circuit accordingto the second embodiment.

FIG. 13 is a circuit diagram illustrating an example of a firstconfiguration of a charge pump circuit according to a third embodiment.

FIG. 14 is a timing chart illustrating operation of switches in theexample of the first configuration of the charge pump circuit accordingto the third embodiment.

FIG. 15 is a circuit diagram illustrating an example of a secondconfiguration of the charge pump circuit according to the thirdembodiment.

FIG. 16 is a timing chart illustrating operation of switches in theexample of the second configuration of the charge pump circuit accordingto the third embodiment.

FIG. 17 is a circuit diagram illustrating an example of a thirdconfiguration of the charge pump circuit according to the thirdembodiment.

FIG. 18 is a timing chart illustrating operation of switches in theexample of the third configuration of the charge pump circuit accordingto the third embodiment.

FIG. 19 is a diagram illustrating an example of a configuration of anelectronic circuit system according to a fourth embodiment.

MODE FOR CARRYING OUT THE INVENTION

Hereinafter, embodiments of the present technology are described withreference to the drawings. Note that, the description will be given inthe following order.

1. First embodiment: current source vertical stack type

2. Second embodiment: charge canceling type

3. Third embodiment: charge canceling type (including potentialgeneration means)

4. Fourth embodiment: electronic circuit system

5. Modification

1. First Embodiment

In a first embodiment, as a charge pump circuit 100, a configurationwill be described in which a plurality of vertically stacked transistorsis provided on the current source side.

Note that, the charge pump circuit 100 may operate as a current sink(drawing) for current discharge, or may operate as a current source thatsupplies (injects) a charging current. In the following description, theformer is referred to as a “sink-type”, and the latter is referred to asa “source-type”, and configurations and operations will be described inorder of a sink-type charge pump circuit 100A, a source-type charge pumpcircuit 100B, and a sink/source integrated-type charge pump circuit100C.

(Circuit Diagram of First Configuration)

FIG. 1 is a circuit diagram illustrating an example of a firstconfiguration of the charge pump circuit according to the firstembodiment.

In FIG. 1, the sink-type charge pump circuit 100A includes a constantcurrent circuit 111, transistors Tr11, Tr12, Tr13, Tr14-1 to Tr14-N, andTr15-1 to Tr15-N, switches SW11 to SW14, and capacitance C11. Note that,the transistors Tr11, Tr12, Tr13, Tr14-1 to Tr14-N, and Tr15-1 to Tr15-Ncan be configured as, for example, N-type MOS transistors.

The transistor Tr11 has the drain connected to an output terminal 112,the source connected to the source of the transistor Tr13, and the gateconnected to the switches SW11 and SW12. Furthermore, the N (N: aninteger greater than or equal to 1) vertically stacked transistorsTr14-1 to Tr14-N are connected to the source side of the transistorTr11.

The transistor Tr12 has the drain connected to the constant currentcircuit 111. Furthermore, the gate of the transistor Tr12 is connectedto the drain and the switch SW11. Moreover, the N (N: an integer greaterthan or equal to 1) vertically stacked transistors Tr15-1 to Tr15-N areconnected to the source side of the transistor Tr12, and all the gatesof the transistors Tr15-1 to Tr15-N are connected to the gate of thetransistor Tr12.

The transistor Tr13 has the drain connected to a voltage source (anarbitrary voltage V_(A)), the source connected to the source of thetransistor Tr11, and the gate connected to the switches SW13 and SW14.

Furthermore, the N vertically stacked transistors Tr14-1 to Tr14-N areconnected to the source side of the transistor Tr13.

The N transistors Tr14-1 to Tr14-N are arranged in a cascade on thesource side of the transistors Tr11 and Tr13, and all the gates of thetransistors Tr14-1 to Tr14-N are connected to the gate of the transistorTr12. Note that, the source of the N-th transistor Tr14-N among thevertically stacked transistors Tr14-1 to Tr14-N is connected to a groundnode.

The N transistors Tr15-1 to Tr15-N are arranged in a cascade on thesource side of the transistor Tr12, and all the gates of the transistorsTr15-1 to Tr15-N are connected to the gate of the transistor Tr12. Notethat, the source of the N-th transistor Tr15-N among the verticallystacked transistors Tr15-1 to Tr15-N is connected to the ground node.

Here, the sizes of the transistors Tr in the sink-type charge pumpcircuit 100A have a relationship as indicated in the followingexpressions (1) and (2).

Tr12=Tr11=Tr13  (1)

Tr15=Tr14  (2)

That is, in a case where the channel width (W length) and the channellength (L length) of each transistor Tr can be designed to be arbitraryvalues, the transistor Tr11 and the transistor Tr13 are made to have thechannel width and channel length of the same values as those of thetransistor Tr12. That is, the transistor Tr11, the transistor Tr12, andthe transistor Tr13 have the same channel width (W length) and channellength (L length).

Furthermore, each transistor Tr14 of the transistors Tr14-1 to Tr14-Nand each transistor Tr15 of the transistors Tr15-1 to Tr15-N are made tohave the channel width and channel length of the same values as those ofthe transistor Tr12. That is, the transistors Tr14-1 to Tr14-N and thetransistors Tr15-1 to Tr15-N have the same channel width (W length) andchannel length (L length).

Note that, it is sufficient that the transistors Tr14-1 to Tr14-N andthe transistors Tr15-1 to Tr15-N have the same channel width and channellength not only in a case where they have the same number of multipliersand fingers of the transistors but also in a case where they have thedifferent number of multipliers and fingers of the transistors. That is,for example, for the purpose of improving the relative variation ofnoise and transistors, there is a case where the number of multipliersor fingers is changed in the transistor Tr12 and the transistor Tr15although the channel width and the channel length are the same as thoseof the transistor Tr11 and the transistor Tr14; however, even in such acase, the configuration of the present technology can be adopted.

The switch SW11 has one end connected to the gate of the transistorTr11, and the other end connected to the gate of the transistor Tr12 andthe gates of the transistors Tr15-1 to Tr15-N.

The switch SW11 performs switching operation depending on a controlsignal input to the switch SW11. When turned on, the switch SW11electrically connects the gate of the transistor Tr11 to the gates ofthe transistors Tr12 and Tr15-1 to Tr15-N.

The switch SW12 has one end connected to the gate of the transistorTr11, and the other end connected to the ground node. The switch SW12performs switching operation depending on a control signal input to theswitch SW12. When turned on, the switch SW12 connects the gate of thetransistor Tr11 to the ground node.

The switch SW13 has one end connected to the gate of the transistorTr13, and the other end connected to the gate of the transistor Tr12,the gates of the transistors Tr15-1 to Tr15-N, and the gates of thetransistors Tr14-1 to Tr14-N.

The switch SW13 performs switching operation depending on a controlsignal input to the switch SW13. When turned on, the switch SW13electrically connects the gate of the transistor Tr13 to the gate of thetransistor Tr12, the gates of the transistors Tr15-1 to Tr15-N, and thegates of the transistors Tr14-1 to Tr14-N.

The switch SW14 has one end connected to the gate of the transistorTr13, and the other end connected to the ground node. The switch SW14performs switching operation depending on a control signal input to theswitch SW14. When turned on, the switch SW14 connects the gate of thetransistor Tr13 to the ground node.

The capacitance C11 has one electrode connected to a signal line betweenthe gate of the transistor Tr12 and the switch SW11, and the otherelectrode connected to the ground node.

(Operation of First Configuration)

Next, with reference to a timing chart of FIG. 2, operation will bedescribed of the sink-type charge pump circuit 100A illustrated inFIG. 1. In A to D of FIG. 2, levels are illustrated of the controlsignals input to the switches SW11 to SW14, respectively, and eachswitch SW performs switching operation depending on the control signalof an H level or a L level.

In FIG. 2, a period from time t12 to time t13 is a current output periodin which a current is output from the output terminal 112. During thecurrent output period, the switches SW11 and SW14 are turned on, and thegate of the transistor Tr11 is electrically connected to the gate of thetransistor Tr12 and the gates of the transistors Tr15-1 to Tr15-N, andthe gate of the transistor Tr13 is connected to the ground node.

As described above, when the current source is turned on during thecurrent output period, switching control is performed so that theswitches SW11 and SW14 are turned on and the switches SW12 and SW13 areturned off, whereby the transistors Tr12 and Tr15-1 to Tr15-N, and thetransistor Tr11 and the transistors Tr14-1 to Tr14-N have the sameconfiguration in a state where the current source is turned on, so thatit is possible to perform current mirror operation and output anintended current.

Here, the transistor Tr12 and the transistors Tr15-1 to Tr15-N have thesame channel width (W: W length) and channel length (L: L length) asthose of the transistor Tr11 and the transistors Tr14-1 to Tr14-N, sothat if the transistor Tr12 and the transistors Tr15-1 to Tr15-N arecombined with the transistor Tr11 and the transistors Tr14-1 to Tr14-N,they behave as a transistor having a characteristic indicated in thefollowing expression (3).

W/(N+1)×L  (3)

From the characteristic indicated in the expression (3), it is meantthat, in the sink-type charge pump circuit 100A, a current source havinga large channel length (L length) in a conventional charge pump circuitis divided into N+1.

Then, in view of the above, since only the transistor Tr11 performsswitching, a parasitic capacitance component of the current source gateto which the switch is connected is reduced to 1/(N+1) compared to thecurrent source having the large channel length (L length) in theconventional charge pump circuit. As a result, a capacitance value (acapacitance value of the capacitance C11) for suppressing a decrease ina sink current value due to charge sharing can be reduced to 1/(N+1), sothat the circuit area can be greatly reduced.

On the other hand, in FIG. 2, during a period excluding the power outputperiod, that is, during a period from time t11 to time t12 and a periodon and after time t13, the switches SW12 and SW13 are turned on, and thegate of the transistor Tr11 is connected to the ground node, and thegate of the transistor Tr13 is electrically connected to the gate of thetransistor Tr12, the gates of the transistors Tr15-1 to Tr15-N, and thegates of the transistors Tr14-1 to Tr14-N.

As described above, when the current source is turned off during theperiod excluding the current output period, switching control isperformed so that the switches SW11 and SW14 are turned off and theswitches SW12 and SW13 are turned on, whereby the transistor Tr13 andthe transistors Tr14-1 to Tr14-N have a current mirror configurationwith the transistor Tr12 and the transistors Tr15-1 to Tr15-N in a statewhere the current source is turned off, so that current steeringoperation is performed in which an arbitrary current is supplied on anarbitrary voltage side.

As a result, the output current source always outputs a currentcontinuously to the output terminal 112 or to an arbitrary voltage, sothat a source voltage of the transistor Tr11 and the transistor Tr13does not fluctuate, and high-speed current on/off operation can beimplemented. Furthermore, since the current is always outputcontinuously, there is an advantage that unnecessary current spurious isnot generated in a power supply or a ground, and does not become anaggressor (a circuit that generates noise) to a peripheral circuit.

Note that, in the timing chart of FIG. 2, the timings of turning on/offthe switches SW11 to SW14 have been described as being all switchedsimultaneously at time t12, time t13, and the like for convenience ofdescription; however, the on/off timings of the switches SW11 and SW12or the on/off timings of the switches SW13 and SW14 are slightly shiftedactually, whereby an outflow is suppressed of electric charges due tosimultaneous turning on of the switches SW11 and SW12 or simultaneousturning on of the switches SW13 and SW14.

As described above, in the sink-type charge pump circuit 100A, thecurrent mirror source transistor is configured by the N verticallystacked transistors Tr15-1 to Tr15-N and the transistor Tr12, and theoutput current source side is configured by the N vertically stackedtransistors Tr14-1 to Tr14-N, the transistor Tr11 drain-connected to theoutput side, and the transistor Tr13 whose source is made common to thatof the transistor Tr11 and that is drain-connected to the arbitraryvoltage (V_(A)). By adopting such a configuration, the capacitance value(the capacitance value of the capacitance C11) arranged in the circuitcan be reduced, and as a result, the circuit area can be reduced.

(Circuit Diagram of Second Configuration)

FIG. 3 is a circuit diagram illustrating an example of a secondconfiguration of the charge pump circuit according to the firstembodiment.

In FIG. 3, the source-type charge pump circuit 100B includes a constantcurrent circuit 121, transistors Tr21, Tr22, Tr23, Tr24-1 to Tr24-N, andTr25-1 to Tr25-N, switches SW21 to SW24, and capacitance C21. Note that,the transistors Tr21, Tr22, Tr23, Tr24-1 to Tr24-N, and Tr25-1 to Tr25-Ncan be configured as, for example, P-type MOS transistors.

The transistor Tr21 has the drain connected to the output terminal 122,the source connected to the source of the transistor Tr23, and the gateconnected to the switches SW21 and SW22. Furthermore, the N (N: aninteger greater than or equal to 1) vertically stacked transistorsTr24-1 to Tr24-N are connected to the source side of the transistorTr21.

The transistor Tr22 has the drain connected to the constant currentcircuit 121. Furthermore, the gate of the transistor Tr22 is connectedto the drain and the switch SW21. Moreover, N (N: an integer greaterthan or equal to 1) vertically stacked transistors Tr25-1 to Tr25-N areconnected to the source side of the transistor Tr22, and all the gatesof the transistors Tr25-1 to Tr25-N are connected to the gate of thetransistor Tr22.

The transistor Tr23 has the drain connected to the voltage source (thearbitrary voltage V_(A)), the source connected to the source of thetransistor Tr21, and the gate connected to the switches SW23 and SW24.

Furthermore, the N vertically stacked transistors Tr24-1 to Tr24-N areconnected to the source side of the transistor Tr23.

The N transistors Tr24-1 to Tr24-N are arranged in a cascade on thesource side of the transistors Tr21 and Tr23, and all the gates of thetransistors Tr24-1 to Tr24-N are connected to the gate of the transistorTr22. Note that, the source of the N-th transistor Tr24-N among thevertically stacked transistors Tr24-1 to Tr24-N is connected to a powersupply node.

The N transistors Tr25-1 to Tr25-N are arranged in a cascade on thesource side of the transistor Tr22, and all the gates of the transistorsTr25-1 to Tr25-N are connected to the gate of the transistor Tr22. Notethat, the source of the N-th transistor Tr25-N among the verticallystacked transistors Tr25-1 to Tr25-N is connected to the power supplynode.

Here, the sizes of the transistors Tr in the source-type charge pumpcircuit 100B have a relationship as indicated in the followingexpressions (4) and (5).

Tr22=Tr21=Tr23  (4)

Tr25=Tr24  (5)

That is, the transistor Tr21, the transistor Tr22, and the transistorTr23 have the same channel width (W length) and channel length (Llength). Furthermore, the transistors Tr24-1 to Tr24-N and thetransistors Tr25-1 to Tr25-N have the same channel width (W length) andchannel length (L length).

The switch SW21 has one end connected to the gate of the transistorTr21, and the other end connected to the gate of the transistor Tr22 andthe gates of the transistors Tr25-1 to Tr25-N. The switch SW21 performsswitching operation depending on a control signal input to the switchSW21.

The switch SW22 has one end connected to the gate of the transistorTr21, and the other end connected to the power supply node. The switchSW22 performs switching operation depending on a control signal input tothe switch SW22.

The switch SW23 has one end connected to the gate of the transistorTr23, and the other end connected to the gate of the transistor Tr22,the gates of the transistors Tr25-1 to Tr25-N, and the gates of thetransistors Tr24-1 to Tr24-N. The switch SW23 performs switchingoperation depending on a control signal input to the switch SW23.

The switch SW24 has one end connected to the gate of the transistorTr23, and the other end connected to the power supply node. The switchSW24 performs switching operation depending on a control signal input tothe switch SW24.

The capacitance C21 has one electrode connected to a signal line betweenthe gate of the transistor Tr22 and the switch SW21, and the otherelectrode connected to the power supply node.

(Operation of Second Configuration)

Next, with reference to a timing chart of FIG. 4, operation will bedescribed of the source-type charge pump circuit 100B illustrated inFIG. 3. In A to D of FIG. 4, levels are illustrated of the controlsignals input to the switches SW21 to SW24, respectively.

In FIG. 4, during the current output period, that is, from time t22 totime t23, the switches SW21 and SW24 are turned on, and the gate of thetransistor Tr21 is electrically connected to the gate of the transistorTr22 and the gates of the transistors Tr25-1 to Tr25-N, and the gate ofthe transistor Tr23 is connected to the power supply node.

By performing such switching control, in a state where the currentsource is turned on, the transistor Tr22 and the transistors Tr25-1 toTr25-N, and the transistor Tr21 and the transistors Tr24-1 to Tr24-Nhave the same configuration, so that it is possible to perform currentmirror operation and output an intended current.

Note that, the principle that a capacitance value (a capacitance valueof the capacitance C21) for suppressing a decrease in an injection(source) current value due to charge sharing can be reduced to 1/(N+1)is basically similar to that described above, so that the descriptionthereof is omitted here. However, also in this case, the circuit areacan be reduced by setting the capacitance value to 1/(N+1).

On the other hand, in FIG. 4, during a period excluding the currentoutput period, that is, during a period from time t21 to time t22 and aperiod on and after time t23, the switches SW22 and SW23 are turned on,and the gate of the transistor Tr21 is connected to the power supplynode, and the gate of the transistor Tr23 is electrically connected tothe gate of the transistor Tr22, the gates of the transistors Tr25-1 toTr25-N, and the gates of the transistors Tr24-1 to Tr24-N.

By performing such switching control, in a state where the currentsource is turned off, the transistor Tr23 and the transistors Tr24-1 toTr24-N have a current mirror configuration with the transistor Tr22 andthe transistors Tr25-1 to Tr25-N, so that current steering operation forsupplying an arbitrary current is performed on an arbitrary voltageside. As a result, it is possible to perform high-speed current on/offoperation as described above, for example.

Note that, in the timing chart of FIG. 4, similarly to the timing chartof FIG. 2 described above, the on/off timings of the switches SW21 andSW22 (or the switches SW23 and SW24) are slightly shifted, whereby anoutflow can be suppressed of electric charges due to simultaneousturning on of the switches SW21 and SW22 (or the switches SW23 andSW24).

In the above, the configuration and operation have been described of thesource-type charge pump circuit 100B.

(Circuit Diagram of Third Configuration)

FIG. 5 is a circuit diagram illustrating an example of a thirdconfiguration of the charge pump circuit according to the firstembodiment.

As illustrated in FIG. 5, the sink/source integrated-type charge pumpcircuit 100C is a charge pump circuit in which the sink-type charge pumpcircuit 100A (FIG. 1) and the source-type charge pump circuit 100B (FIG.3) are integrated together.

In FIG. 5, the sink/source integrated-type charge pump circuit 100Cincludes a constant current circuit 131, transistors Tr31, Tr32, Tr33,Tr34-1 to Tr34-N, and Tr35-1 to Tr35-N, switches SW31 to SW34, andcapacitance C31, and a constant current circuit 132, transistors Tr36,Tr37, Tr38, Tr39-1 to Tr39-M, and Tr310-1 to Tr310-M, switches SW35 toSW38, and capacitance C32.

In the sink/source integrated-type charge pump circuit 100C, theconstant current circuit 131, the transistors Tr31, Tr32, Tr33, Tr34-1to Tr34-N, and Tr35-1 to Tr35-N, the switches SW31 to SW34, and thecapacitance C31 correspond to the constant current circuit 111, thetransistors Tr11, Tr12, Tr13, Tr14-1 to Tr14-N, and Tr15-1 to Tr15-N,the switches SW11 to SW14, and the capacitance C11 of the sink-typecharge pump circuit 100A (FIG. 1).

Furthermore, in the sink/source integrated-type charge pump circuit100C, the constant current circuit 132, the transistors Tr36, Tr37,Tr38, Tr39-1 to Tr39-M, and Tr310-1 to Tr310-M, the switches SW35 toSW38, and the capacitance C32 correspond to the constant current circuit121, the transistors Tr21, Tr22, Tr23, Tr24-1 to Tr24-N, and Tr25-1 toTr25-N, the switches SW21 to SW24, and the capacitance C21 of thesource-type charge pump circuit 100B (FIG. 3).

Moreover, in the sink/source integrated-type charge pump circuit 100C,an output terminal 133 corresponds to the output terminal 112 of thesink-type charge pump circuit 100A (FIG. 1) or the output terminal 122of the source-type charge pump circuit 100B (FIG. 3).

That is, the sink/source integrated-type charge pump circuit 100Cincludes the transistors Tr31, Tr32, Tr33, Tr34-1 to Tr34-N, and Tr35-1to Tr35-N, the switches SW31 to SW34, and the capacitance C31 aselements on the sink-type side, and includes the transistors Tr36, Tr37,Tr38, Tr39-1 to Tr39-M, and Tr310-1 to Tr310-M, the switches SW35 toSW38, and the capacitance C32 as elements on the source-type side.

Note that, the sizes of the transistors Tr on the sink-type side and thesource-type side in the sink/source integrated-type charge pump circuit100C have a relationship as indicated in the following expressions (6)to (9).

Tr32=Tr31=Tr33  (6)

Tr35=Tr34  (7)

Tr37=Tr36=Tr38  (8)

Tr310=Tr39  (9)

That is, the transistor Tr31, the transistor Tr32, and the transistorTr33 have the same channel width (W length) and channel length (Llength). Furthermore, the transistors Tr34-1 to Tr34-N and thetransistors Tr35-1 to Tr35-N have the same channel width (W length) andchannel length (L length).

Moreover, the transistor Tr36, the transistor Tr37, and the transistorTr38 have the same channel width (W length) and channel length (Llength). Furthermore, the transistors Tr39-1 to Tr39-N and thetransistors Tr310-1 to Tr310-N have the same channel width (W length)and channel length (L length).

(Operation of Third Configuration)

Next, with reference to a timing chart of FIG. 6, operation will bedescribed of the sink/source integrated-type charge pump circuit 100Cillustrated in FIG. 5. In A to D of FIG. 6, levels are illustrated ofthe control signals input to the switches SW31 to SW34 on the sink-typeside, and in E to H of FIG. 6, levels are illustrated of the controlsignals input to the switches SW35 to SW38 on the source-type side.

In A to D of FIG. 6, during the current output period on the sink-typeside, that is, from time t32 to time t33, the switches SW31 and SW34 areturned on, and the gate of the transistor Tr31 is electrically connectedto the gate of the transistor Tr32 and the gates of the transistorTr35-1 to Tr35-N, and the gate of the transistor Tr33 is connected tothe ground node.

On the other hand, in A to D of FIG. 6, during a period excluding thecurrent output period on the sink-type side, that is, during a periodfrom time t31 to time t32 and a period on and after time t33, theswitches SW32 and SW33 are turned on, and the gate of the transistorTr31 is connected to the ground node, and the gate of the transistorTr33 is electrically connected to the gate of the transistor Tr32, thegates of the transistors Tr35-1 to Tr35-N, and the gates of thetransistors Tr34-1 to Tr34-N.

Furthermore, in E to H of FIG. 6, during the current output period onthe source-type side, that is, from time t36 to time t37, the switchesSW35 and SW38 are turned on, and the gate of the transistor Tr36 iselectrically connected to the gate of the transistor Tr37, and the gatesof the transistors Tr310-1 to Tr310-N, and the gate of the transistorTr38 is connected to the power supply node.

On the other hand, in E to H in FIG. 6, during a period excluding thecurrent output period on the source-type side, that is, during a periodfrom time t35 to time t36 and a period on and after time t37, theswitches SW36 and SW37 are turned on, and the gate of the transistorTr36 is connected to the power supply node, and the gate of thetransistor Tr38 is electrically connected to the gate of the transistorTr37, the gates of the transistors Tr310-1 to Tr310-N, and the gates ofthe transistors Tr39-1 to Tr39-N.

Note that, details of the operation and the principle of suppressing adecrease in a sink or source (injection) current value due to chargesharing by arranging capacitance values (capacitance values of thecapacitances C31 and C32) to be 1/(N+1) are basically similar to thosedescribed above, so that the descriptions thereof are omitted here.

In the above, the configuration and operation have been described of thesink/source integrated-type charge pump circuit 100C.

2. Second Embodiment

In a second embodiment, a configuration will be described in which acharge canceling mechanism is provided in a case where a gate switchingtype configuration is adopted as a charge pump circuit 200. In thefollowing description, configurations and operations will be describedin order of a sink-type charge pump circuit 200A, a source-type chargepump circuit 200B, and a sink/source integrated-type charge pump circuit200C.

(Circuit Diagram of First Configuration)

FIG. 7 is a circuit diagram illustrating an example of a firstconfiguration of the charge pump circuit according to the secondembodiment.

In FIG. 7, the sink-type charge pump circuit 200A includes a currentsource transistor Tr41, switches SW41 to SW44, and capacitance C41.

The current source transistor Tr41 is configured as, for example, anN-type MOS transistor. In the current source transistor Tr41, the drainis connected to an output terminal 211, the source is connected to theground node, and the gate is connected to the switches SW41 and SW42.

The switch SW41 has one end connected to the gate of the current sourcetransistor Tr41, and the other end connected to a signal line L41 towhich a voltage V₁ from an input terminal 212 is applied. The switchSW41 performs switching operation depending on a control signal input tothe switch SW41. When turned on, the switch SW41 electrically connectsthe gate of the current source transistor Tr41 to the signal line L41.

The switch SW42 has one end connected to the gate of the current sourcetransistor Tr41, and the other end connected to the ground node. Theswitch SW42 performs switching operation depending on a control signalinput to the switch SW42. When turned on, the switch SW42 connects thegate of the current source transistor Tr41 to the ground node.

Here, in the sink-type charge pump circuit 200A, the charge cancelingmechanism is provided for such a gate switching type configuration,whereby capacitance (sufficiently large capacitance) for suppressing adecrease in a current value is unnecessary (or the capacitance isreduced). That is, in the charge canceling mechanism, the capacitanceC41 is provided for the signal line L41 (current mirror source side)between the switch SW41 and the input terminal 212, and it is enabled toarbitrarily switch a potential of a connection destination of thecapacitance C41 by the switches SW43 and SW44.

More specifically, the charge canceling mechanism is configured asfollows. That is, the capacitance C41 has one electrode connected to thesignal line L41, and the other electrode connected to the switches SW43and SW44.

The switch SW43 has one end connected between the capacitance C41 (theother electrode thereof) and the switch SW44, and the other endconnected to a signal line L43 to which a voltage V_(A)−V₁ from an inputterminal 213 is applied. The switch SW43 performs switching operationdepending on a control signal input to the switch SW43. When turned on,the switch SW43 electrically connects the capacitance C41 (the otherelectrode thereof) to the signal line L43.

The switch SW44 has one end connected to the capacitance C41 (the otherelectrode thereof), and the other end connected to a signal line L42 towhich the arbitrary voltage V_(A) by the voltage source is applied. Theswitch SW44 performs switching operation depending on a control signalinput to the switch SW44. When turned on, the switch SW44 electricallyconnects the capacitance C41 (the other electrode thereof) to the signalline L42.

Here, in the charge canceling mechanism, when a voltage applied to thesignal line L41 connected to the input terminal 212 is set to thevoltage V₁, and a voltage applied to the signal line L42 connected tothe voltage source is set to the voltage V_(A), a voltage applied to thesignal line L43 connected to the input terminal 213 is set to thevoltage V_(A)−V₁ that is a difference voltage between the voltage V_(A)and the voltage V1. That is, as arbitrarily switchable voltages of theconnection destination of the capacitance C41 (the other electrodethereof), one voltage is set to the voltage V_(A), and the other voltageis set to the voltage V_(A)−V₁.

At this time, by setting a value of the capacitance C41 to the samevalue as a parasitic capacitance component depending on the gate node ofthe current source transistor Tr41, as for the amount of charge sharingto the parasitic capacitance on the gate side, generated chargeinjection into the current mirror becomes equal by a potential change(ΔV=V₁) of the connection destination of the capacitance C41, and adecrease in the sink current value due to the charge sharing can besuppressed in principle.

This means that, in the configuration of the conventional gate switchingtype charge pump circuit, it has been necessary to arrange asufficiently large capacitance value compared to the parasiticcapacitance on the current source gate side, but it is only required toarrange capacitance equivalent to the parasitic capacitance; as aresult, the circuit area can be reduced.

(Operation of First Configuration)

Next, with reference to a timing chart of FIG. 8, operation will bedescribed of the sink-type charge pump circuit 200A illustrated in FIG.7. In A to D of FIG. 8, levels are illustrated of the control signalsinput to the switches SW41 to SW44, respectively, and each switch SWperforms switching operation depending on the control signal of the Hlevel or the L level.

In FIG. 8, a period from time t42 to time t43 is the current outputperiod in which a current is output from the output terminal 211. Duringthe current output period, the switches SW41 and SW44 are turned on, andthe gate of the current source transistor Tr41 is electrically connectedto the signal line L41 to which the voltage V₁ is applied, and thecapacitance C41 (the other electrode thereof) connected to the signalline L41 is electrically connected to the signal line L42 to which thevoltage V_(A) is applied.

On the other hand, in FIG. 8, during a period excluding the currentoutput period, that is, during a period from time t41 to time t42 and aperiod on and after time t43, the switches SW42 and SW43 are turned on,and the gate of the current source transistor Tr41 is connected to theground node, and the capacitance C41 (the other electrode thereof) iselectrically connected to the signal line L43 to which the voltageV_(A)−V₁ is applied.

Here, by performing exclusive control on the switches SW41 and SW42 andperforming exclusive control on the switches SW43 and SW44, when thecurrent output period is reached, the connection destination of thecapacitance C41 is changed from the signal line L43 to which the voltageV_(A)−V₁ is applied to the signal line L42 to which the voltage V_(A) isapplied, and a potential change (ΔV=V₁) occurs, and shared charges canbe charged from the charge canceling mechanism (the capacitance C41thereof) side, so that it is possible to suppress a decrease in the sinkcurrent value due to the charge sharing.

Note that, in the timing chart of FIG. 8, the timings of turning on/offthe switches SW41 to SW44 have been described as being all switchedsimultaneously at time t42, time t43, and the like for convenience ofdescription; however, the on/off timings of the switches SW41 and SW42or the on/off timings of the switches SW43 and SW44 are slightly shiftedactually, whereby an outflow is suppressed of electric charges due tosimultaneous turning on of the switches SW41 and SW42 or simultaneousturning on of the switches SW43 and SW44.

As described above, in the sink-type charge pump circuit 200A, thecharge canceling mechanism is provided, whereby it is possible inprinciple to suppress the decrease in the sink current value caused bythe charge sharing to the parasitic capacitance at the gate node of thecurrent source. At that time, it is only required to arrange thecapacitance equivalent to the parasitic capacitance as the capacitanceC41, so that the circuit area can be reduced as a result.

For example, as disclosed in Patent Document 1 described above, when acurrent source is turned on at the time of source (injection) or sink,charge sharing occurs to a capacitance component existing at the gate ofthe current source transistor, so that the output current is less thanthe current value obtained by the original current mirror. To suppressthis, it is necessary to arrange a sufficiently large capacitance beforethe switch, and the circuit area increases as described above. Notethat, the current source transistor often uses the channel length (Llength) thickly in general and the capacitance seen from the gate sidehas a large capacitance value, and here, it is necessary to arrangecapacitance larger than the capacitance value.

On the other hand, in the sink-type charge pump circuit 200A, when thecharge canceling mechanism is provided for the gate switching typeconfiguration, it is only required to arrange the capacitance C41equivalent to the parasitic capacitance of the gate node of the currentsource transistor Tr41, so that the circuit area can be reduced. As aresult, in the gate switching type charge pump circuit 200A, it ispossible to reduce the circuit area while enabling reduction of a leakcurrent and low voltage operation.

(Circuit Diagram of Second Configuration)

FIG. 9 is a circuit diagram illustrating an example of a secondconfiguration of the charge pump circuit according to the secondembodiment.

In FIG. 9, the source-type charge pump circuit 200B includes a currentsource transistor Tr51, switches SW51 to SW54, and capacitance C51.

The current source transistor Tr51 is configured as, for example, aP-type MOS transistor. In the current source transistor Tr51, the drainis connected to an output terminal 221, the source is connected to thepower supply node, and the gate is connected to the switches SW51 andSW52.

The switch SW51 has one end connected to the gate of the current sourcetransistor Tr51, and the other end connected to a signal line L51 towhich a voltage V_(dd)−V₁ from an input terminal 222 is applied. Theswitch SW51 performs switching operation depending on a control signalinput to the switch SW51. When turned on, the switch SW51 electricallyconnects the gate of the current source transistor Tr51 to the signalline L51.

The switch SW52 has one end connected to the gate of the current sourcetransistor Tr51, and the other end connected to the power supply node.The switch SW52 performs switching operation depending on a controlsignal input to the switch SW52, and when turned on, connects the gateof the current source transistor Tr51 to the power supply node.

Here, in the source-type charge pump circuit 200B, the capacitance C51is provided as the charge canceling mechanism for such a gate switchingtype configuration, and it is enabled to arbitrarily switch a potentialof the connection destination of the capacitance C51 by the switchesSW53 and SW54.

More specifically, the charge canceling mechanism is configured asfollows. That is, the capacitance C51 has one electrode connected to thesignal line L51, and the other electrode connected to the switches SW53and SW54.

The switch SW53 has one end connected between the capacitance C51 (theother electrode thereof) and the switch SW54, and the other endconnected to a signal line L53 to which a voltage V_(A)+V₁ from an inputterminal 223 is applied. The switch SW53 performs switching operationdepending on a control signal input to the switch 53, and when turnedon, connects the capacitance C51 (the other electrode thereof) to thesignal line L53.

The switch SW54 has one end connected to the capacitance C51 (the otherelectrode thereof), and the other end connected to a signal line L52 towhich the arbitrary voltage V_(A) by the voltage source is applied. Theswitch SW54 performs switching operation depending on a control signalinput to the switch SW54, and when turned on, connects the capacitanceC51 (the other electrode thereof) to the signal line L52.

Here, in the charge canceling mechanism, when a voltage applied to thesignal line L51 connected to the input terminal 222 is set to thevoltage V_(dd)−V₁, and a voltage applied to the signal line L52connected to the voltage source is set to the voltage V_(A), a voltageapplied to the signal line L53 connected to the input terminal 223 isset to the voltage V_(A)+V₁ that is a sum of the voltage V_(A) and thevoltage V₁. That is, as arbitrarily switchable voltages of theconnection destination of the capacitance C51 (the other electrodethereof), one voltage is set to the voltage V_(A), and the other voltageis set to the voltage V_(A)+V₁.

Note that, the principle of suppressing a decrease in the source(injection) current value due to charge sharing by arranging capacitanceequivalent to the parasitic capacitance of the gate node of the currentsource transistor Tr51 as the capacitance C51 is basically similar tothat described above, so that the description thereof is omitted here.However, also in this case, the circuit area can be reduced by arrangingthe capacitance C51 equivalent to the parasitic capacitance as thecharge canceling mechanism.

(Operation of Second Configuration)

Next, with reference to a timing chart of FIG. 10, operation will bedescribed of the source-type charge pump circuit 200B illustrated inFIG. 9. In A to D of FIG. 10, levels (H level, L level) are illustratedof the control signals input to the switches SW51 to SW54, respectively.

In FIG. 10, during the current output period, that is, from time t52 totime t53, the switches SW51 and SW54 are turned on, and the gate of thecurrent source transistor Tr51 is electrically connected to the signalline L51 to which the voltage V_(dd)−V₁ is applied, and the capacitanceC51 (the other electrode thereof) connected to the signal line L51 iselectrically connected to the signal line L52 to which the voltage V_(A)is applied.

On the other hand, in FIG. 10, during a period excluding the currentoutput period, that is, during a period from time t51 to time t52 and aperiod on and after time t53, the switches SW52 and SW53 are turned on,and the gate of the current source transistor Tr51 is connected to thepower supply node, and the capacitance C51 (the other electrode thereof)is electrically connected to the signal line L53 to which the voltageV_(A)+V₁ is applied.

Here, by performing exclusive control on the switches SW51 and SW52 andperforming exclusive control on the switches SW53 and SW54, when thecurrent output period is reached, the connection destination of thecapacitance C51 is changed from the signal line L53 to which the voltageV_(A)+V₁ is applied to the signal line L52 to which the voltage V_(A) isapplied, and a potential change (ΔV=V₁) occurs, and shared charges canbe charged from the charge canceling mechanism (the capacitance C51thereof) side, so that it is possible to suppress a decrease in thesource (injection) current value due to the charge sharing.

Note that, in the timing chart of FIG. 10, similarly to the timing chartof FIG. 8 described above, the on/off timings of the switches SW51 andSW52 (or the switches SW53 and SW54) are slightly shifted, whereby anoutflow can be suppressed of electric charges due to simultaneousturning on of the switches SW51 and SW52 (or the switches SW53 andSW54).

In the above, the configuration and operation have been described of thesource-type charge pump circuit 200B.

(Circuit Diagram of Third Configuration)

FIG. 11 is a circuit diagram illustrating an example of a thirdconfiguration of the charge pump circuit according to the secondembodiment.

As illustrated in FIG. 11, the sink/source integrated-type charge pumpcircuit 200C is a charge pump circuit in which the sink-type charge pumpcircuit 200A (FIG. 7) and the source-type charge pump circuit 200B (FIG.9) are integrated together.

In FIG. 11, the sink/source integrated-type charge pump circuit 200Cincludes a current source transistor Tr61, switches SW61 to SW64, andcapacitance C61, and a current source transistor Tr62, switches SW65 toSW68, and capacitance C62.

In the sink/source integrated-type charge pump circuit 200C, the currentsource transistor Tr61, the switches SW61 to SW64, and the capacitanceC61 correspond to the current source transistor Tr41, the switches SW41to SW44, and the capacitance C41 of the sink-type charge pump circuit200A (FIG. 7).

Furthermore, in the sink/source integrated-type charge pump circuit200C, the current source transistor Tr62, the switches SW65 to SW68, andthe capacitance C62 correspond to the current source transistor Tr51,the switches SW51 to SW54, and the capacitance C51 of the source-typecharge pump circuit 200B (FIG. 9).

Moreover, in the sink/source integrated-type charge pump circuit 200C,an output terminal 231 corresponds to the output terminal 211 (FIG. 7)or the output terminal 221 (FIG. 9), input terminals 232 and 233correspond to the input terminals 212 and 213 (FIG. 7), and inputterminals 234 and 235 correspond to the input terminals 222 and 223(FIG. 9).

That is, in the sink/source integrated-type charge pump circuit 200C,the charge canceling mechanism is provided for each of the gateswitching type configurations on the sink-type side and the source-typeside.

In the charge canceling mechanism on the sink-type side, as arbitrarilyswitchable voltages of the connection destination of the capacitance C61(the other electrode thereof), one voltage is set to the voltage V_(A),and the other voltage is set to the voltage V_(A)−V₁. Furthermore, inthe charge canceling mechanism on the source-type side, as arbitrarilyswitchable voltages of the connection destination of the capacitance C62(the other electrode thereof), one voltage is set to a voltage V_(B),and the other voltage is set to a voltage V_(B)+V₂.

(Operation of Third Configuration)

Next, with reference to a timing chart of FIG. 12, operation will bedescribed of the sink/source integrated-type charge pump circuit 200Cillustrated in FIG. 11. In A to D of FIG. 12, levels are illustrated ofthe control signals input to the switches SW61 to SW64 on the sink-typeside, and in E to H of FIG. 12, levels are illustrated of the controlsignals input to the switches SW65 to SW68 on the source-type side.

In A to D of FIG. 12, during the current output period on the sink-typeside, that is, from time t62 to time t63, the switches SW61 and SW64 areturned on, and the gate of the current source transistor Tr61 iselectrically connected to the signal line L61 to which the voltage V₁ isapplied, and the capacitance C61 (the other electrode thereof) iselectrically connected to the signal line L62 to which the voltage V_(A)is applied.

On the other hand, in A to D of FIG. 12, during a period excluding thecurrent output period on the sink-type side, that is, during a periodfrom time t61 to time t62 and a period on and after time t63, theswitches SW62 and SW63 are turned on, and the gate of the current sourcetransistor Tr61 is connected to the ground node, and the capacitance C61(the other electrode thereof) is electrically connected to the signalline L63 to which the voltage V_(A)−V₁ is applied.

Furthermore, in E to H of FIG. 12, during the current output period onthe source-type side, that is, from time t66 to time t67, the switchesSW65 and SW68 are turned on, and the gate of the current sourcetransistor Tr62 is electrically connected to the signal line L64 towhich a voltage V_(dd)−V₂ is applied, and the capacitance C62 (the otherelectrode thereof) is electrically connected to the signal line L65 towhich the voltage V_(B) is applied.

On the other hand, in E to H of FIG. 12, during a period excluding thecurrent output period on the source-type side, that is, during a periodfrom time t65 to time t66 and a period on and after time t67, theswitches SW66 and SW67 are turned on, and the gate of the current sourcetransistor Tr62 is electrically connected to the power supply node, andthe capacitance C62 (the other electrode thereof) is electricallyconnected to the signal line L66 to which the voltage V_(B)+V₂ isapplied.

Note that, details of the operation and the principle of suppressing adecrease in a sink or source (injection) current value due to chargesharing by arranging the capacitances C61 and C62 are basically similarto those described above, so that the descriptions thereof are omittedhere.

In the above, the configuration and operation have been described of thesink/source integrated-type charge pump circuit 200C.

3. Third Embodiment

In a third embodiment, a gate switching type configuration is adopted asa charge pump circuit 300, and a configuration will be describedincluding a specific potential generation means in a case where thecharge canceling mechanism is provided similarly to the secondembodiment described above. In the following description, configurationsand operations will be described in order of a sink-type charge pumpcircuit 300A, a source-type charge pump circuit 300B, and a sink/sourceintegrated-type charge pump circuit 300C.

(Circuit Diagram of First Configuration)

FIG. 13 is a circuit diagram illustrating an example of a firstconfiguration of a charge pump circuit according to the thirdembodiment.

In FIG. 13, the sink-type charge pump circuit 300A is basicallyconfigured similarly to the sink-type charge pump circuit 200A (FIG. 7),but differs in that the sink-type charge pump circuit 300A includes apotential generation means.

That is, in the sink-type charge pump circuit 300A, as compared with thesink-type charge pump circuit 200A (FIG. 7), a constant current circuit312 and a transistor Tr72 are provided instead of the input terminal212, and a constant current circuit 313 and a transistor Tr73 areprovided instead of the input terminal 213.

The transistors Tr72 and Tr73 are configured as, for example, N-type MOStransistors. Note that, in FIG. 13, an output terminal 311 correspondsto the output terminal 211 (FIG. 7), and signal lines L71 to L73correspond to the signal lines L41 to L43 (FIG. 7).

The transistor Tr72 has the gate and drain connected to the constantcurrent circuit 312, and the source connected to the ground node.Furthermore, the gate of the transistor Tr72 is connected to the signalline L71. By supplying a constant current to the drain side of thetransistor Tr72 by the constant current circuit 312, the voltage V₁ canbe applied to the signal line L71.

The transistor Tr73 has the gate and drain connected to the signal lineL72 to which the voltage V_(A) is applied, and the constant currentcircuit 313 is connected to the source side. By supplying a constantcurrent to the source side of the transistor Tr73 by the constantcurrent circuit 313, the voltage V_(A)−V₁ that is the difference voltagebetween the voltage V_(A) and the voltage V₁ can be applied to thesignal line L73.

Note that, in the sink-type charge pump circuit 300A, a current sourcetransistor Tr71, switches SW71 to SW74, and capacitance C71 areconfigured similarly to the current source transistor Tr41, the switchesSW41 to SW44, and the capacitance C41 of the sink-type charge pumpcircuit 200A (FIG. 7), so that the descriptions thereof are omitted.

(Operation of First Configuration)

FIG. 14 is a timing chart for explaining operation of the charge pumpcircuit 300A of FIG. 13. Switching operation of the switches SW71 toSW74 of the charge pump circuit 300A is similar to the operation of theswitches SW41 to SW44 of the charge pump circuit 200A (FIG. 7)illustrated in the timing chart of FIG. 8, so that the descriptionthereof is omitted here.

As described above, in the sink-type charge pump circuit 300A, when thecharge canceling mechanism is provided, the constant current is suppliedfrom the constant current circuit 313 to the transistor Tr73 whose gateand drain are connected to the arbitrary voltage V_(A) so that thecurrent density is equal to that of the transistor Tr72 forming thecurrent mirror, whereby the potential (V_(A)−V₁) can be generated, and adesired potential can be obtained with a simple circuit configuration(very few elements).

(Circuit Diagram of Second Configuration)

FIG. 15 is a circuit diagram illustrating an example of a secondconfiguration of the charge pump circuit according to the thirdembodiment.

In FIG. 15, the source-type charge pump circuit 300B is basicallyconfigured similarly to the source-type charge pump circuit 200B (FIG.9), but differs in that the source-type charge pump circuit 300Bincludes a potential generation means.

That is, in the source-type charge pump circuit 300B, as compared withthe source-type charge pump circuit 200B (FIG. 9), a constant currentcircuit 322 and a transistor Tr82 are provided instead of the inputterminal 222, and a constant current circuit 323 and a transistor Tr83are provided instead of the input terminal 223.

The transistors Tr82 and Tr83 are configured as, for example, P-type MOStransistors. Furthermore, in FIG. 15, an output terminal 321 correspondsto the output terminal 221 (FIG. 9), and signal lines L81 to L83correspond to the signal lines L51 to L53 (FIG. 9).

The transistor Tr82 has the gate and drain connected to the constantcurrent circuit 322, and the source connected to the power supply node.Furthermore, the gate of the transistor Tr82 is connected to the signalline L81. By supplying a constant current to the drain side of thetransistor Tr82 by the constant current circuit 322, the voltageV_(dd)−V₁ can be applied to the signal line L81.

The transistor Tr83 has the gate and drain connected to the signal lineL82 to which the voltage V_(A) is applied, and the constant currentcircuit 323 is connected to the source side. By supplying a constantcurrent to the source side of the transistor Tr83 by the constantcurrent circuit 323, the voltage V_(A)+V₁ that is the sum of the voltageV_(A) and the voltage V₁ can be applied to the signal line L83.

Note that, in the source-type charge pump circuit 300B, a current sourcetransistor Tr81, switches SW81 to SW84, and capacitance C81 areconfigured similarly to the current source transistor Tr51, the switchesSW51 to SW54, and the capacitance C51 of the source-type charge pumpcircuit 200B (FIG. 9), so that the descriptions thereof are omitted.

(Operation of Second Configuration)

FIG. 16 is a timing chart for explaining operation of the charge pumpcircuit 300B of FIG. 15. Switching operation of the switches SW81 toSW84 of the charge pump circuit 300B is similar to the operation of theswitches SW51 to SW54 of the charge pump circuit 200B (FIG. 9)illustrated in the timing chart of FIG. 10, so that the descriptionthereof is omitted here.

In the above, the configuration and operation have been described of thesource-type charge pump circuit 300B.

(Circuit Diagram of Third Configuration)

FIG. 17 is a circuit diagram illustrating an example of a thirdconfiguration of the charge pump circuit according to the thirdembodiment.

In FIG. 17, the sink/source integrated-type charge pump circuit 300C isbasically configured similarly to the sink/source integrated-type chargepump circuit 200C (FIG. 11), but differs in that the sink/sourceintegrated-type charge pump circuit 300C includes a potential generationmeans.

That is, in the sink/source integrated-type charge pump circuit 300C, ascompared with the sink/source integrated-type charge pump circuit 200C(FIG. 11), a constant current circuit 332 and a transistor Tr92, and aconstant current circuit 333 and a transistor Tr93 are providedrespectively instead of the input terminal 232 and the input terminal233 on the sink-type side.

Furthermore, a constant current circuit 334 and a transistor Tr95, and aconstant current circuit 335 and a transistor Tr96 are providedrespectively instead of the input terminal 234 and the input terminal235 on the source-type side. Moreover, in FIG. 17, an output terminal331 corresponds to the output terminal 231 (FIG. 11), and signal linesL91 to L93 on the sink-type side and signal lines L94 to L96 on thesource-type side respectively correspond to the signal lines L61 to L63on the sink-type side (FIG. 11) and the signal lines L64 to L66 on thesource-type side (FIG. 11).

The transistor Tr92 on the sink-type side has the gate and drainconnected to the constant current circuit 332, and the source connectedto the ground node. Furthermore, the gate of the transistor Tr92 isconnected to the signal line L91. By supplying a constant current to thedrain side of the transistor Tr92 by the constant current circuit 332,the voltage V₁ can be applied to the signal line L91.

The transistor Tr93 on the sink-type side has the gate and drainconnected to the signal line L92 to which the voltage V_(A) is applied,and the constant current circuit 333 is connected to the source side. Bysupplying a constant current to the source side of the transistor Tr93by the constant current circuit 333, the voltage V_(A)−V₁ that is thedifference voltage between the voltage V_(A) and the voltage V₁ can beapplied to the signal line L93.

The transistor Tr95 on the source-type side has the gate and drainconnected to the constant current circuit 334, and the source connectedto the power supply node. Furthermore, the gate of the transistor Tr95is connected to the signal line L94. By supplying a constant current tothe drain side of the transistor Tr95 by the constant current circuit334, the voltage V_(dd)−V₂ can be applied to the signal line L94.

The transistor Tr96 has the gate and drain connected to the signal lineL95 to which the voltage V_(B) is applied, and the constant currentcircuit 335 is connected to the source side. By supplying a constantcurrent to the source side of the transistor Tr96 by the constantcurrent circuit 335, the voltage V_(B)+V₂ that is a sum of the voltageV_(B) and the voltage V₂ can be applied to the signal line L96.

Note that, in the sink/source integrated-type charge pump circuit 300C,a current source transistor Tr91, switches SW91 to SW94, and capacitanceC91 on the sink-type side, and a current source transistor Tr94,switches SW95 to SW98, and capacitance C92 on the source-type side areconfigured similarly to the current source transistor Tr61, the switchesSW61 to SW64, and the capacitance C61 on the sink-type side, and thecurrent source transistor Tr62, the switches SW65 to SW68, and thecapacitance C62 on the source-type side of the sink/sourceintegrated-type charge pump circuit 200C (FIG. 11), so that thedescriptions thereof are omitted.

(Operation of Third Configuration)

FIG. 18 is a timing chart for explaining operation of the charge pumpcircuit 300C of FIG. 17. Switching operation of the switches SW91 toSW98 of the charge pump circuit 300C is similar to the operation of theswitches SW61 to SW68 of the charge pump circuit 200C (FIG. 11)illustrated in the timing chart of FIG. 12, so that the descriptionthereof is omitted here.

In the above, the configuration and operation have been described of thesink/source integrated-type charge pump circuit 300C.

4. Fourth Embodiment

(Example of Configuration)

FIG. 19 is a diagram illustrating an example of a configuration of anelectronic circuit system according to a fourth embodiment.

In FIG. 19, an electronic circuit system 1 includes a control circuit 10and the charge pump circuit 100. However, here, although the charge pumpcircuit 100 will be described as an example, the charge pump circuit 200or the charge pump circuit 300 may be provided instead of the chargepump circuit 100.

In the electronic circuit system 1, the control circuit 10 and thecharge pump circuit 100 are connected to each other via control lines L1to Li (i: an integer greater than or equal to 1). For example, in thecharge pump circuit 100, the control lines L1 to Li are connected toswitches SW (for example, the switches SW11 to SW14 of FIG. 1).

The control circuit 10 generates control signals (for example, controlsignals of the H level or the L level) for controlling the switches SWof the charge pump circuit 100, and supplies the control signals to thecharge pump circuit 100 via the control lines L1 to Li. In the chargepump circuit 100, the switches SW perform switching operation on thebasis of the control signals from the control circuit 10 outside,whereby the charge pump circuit 100 operates as a current sink forcurrent discharge, or as a current source that supplies a chargingcurrent.

5. Modification

The charge pump circuits (100, 200, 300) of the first to thirdembodiments described above can be mounted on, for example, a PhaseLocked Loop (PLL) circuit, a Digital to Analog Converter (DAC) having aconfiguration of switching a current source, and the like.

Here, for example, a case is assumed where the charge pump circuit 100(200, 300) is mounted on a PLL circuit including a phase comparator(PC), a charge pump circuit, a low pass filter (LPF), and a voltagecontrolled oscillator (VCO).

In this case, the charge pump circuit 100 (200, 300) performs chargepump operation on the basis of an output pulse from the phase comparatorprovided at the preceding stage. An output of the charge pump circuit100 (200, 300) is output to the low pass filter including a capacitorcharged or discharged by the charge pump circuit 100 (200, 300). Notethat, a voltage of the capacitor of the low pass filter is applied as aninput to the voltage controlled oscillator. Furthermore, the phasecomparator compares a phase of an input signal with a phase of an outputof the voltage controlled oscillator.

Note that, if such a PLL circuit is regarded as the electronic circuitsystem 1 (FIG. 19) described above, it can also be said that the phasecomparator provided before the charge pump circuit 100 (200, 300)corresponds to the control circuit 10 (FIG. 19), and inputs the controlsignals to the charge pump circuit 100 (200, 300).

Note that, the embodiment of the present technology is not limited tothe embodiments described above, and various modifications are possiblewithout departing from the scope of the present technology.

Furthermore, the present technology can have a configuration as follows.

(1)

A charge pump circuit including:

a first transistor including a first terminal, a second terminalconnected to an output terminal, and a control terminal;

a second transistor including a first terminal, a second terminal towhich a constant current is supplied, and a control terminal connectedto the second terminal;

a third transistor including a first terminal connected to the firstterminal of the first transistor, a second terminal connected to avoltage source that supplies an arbitrary voltage, and a controlterminal;

a fourth transistor group including N transistors arranged in a cascadeon a first terminal side of the first transistor, where N is an integergreater than or equal to 1, the N transistors all including controlterminals connected to the control terminal of the second transistor;

a fifth transistor group including N transistors arranged in a cascadeon a first terminal side of the second transistor, the N transistors allincluding control terminals connected to the control terminal of thesecond transistor;

a first switch element that electrically connects the control terminalof the first transistor to the control terminal of the secondtransistor;

a second switch element that connects the control terminal of the firsttransistor to a ground node;

a third switch element that electrically connects the control terminalof the third transistor to the control terminals of the fourthtransistor group and the fifth transistor group; and

a fourth switch element that connects the control terminal of the thirdtransistor to the ground node, in which

the first transistor has a channel width and a channel length identicalto those of the second transistor,

the third transistor has the channel width and the channel lengthidentical to those of the first transistor and the second transistor,

in the fourth transistor group, each of the transistors has the channelwidth and the channel length identical to those of the secondtransistor, and a first terminal of one of the transistors is connectedto the ground node, and

in the fifth transistor group, each of the transistors has the channelwidth and the channel length identical to those of the secondtransistor, and a first terminal of one of the transistors is connectedto the ground node.

(2)

The charge pump circuit according to (1), in which

during a current output period that is a period in which a current isoutput, the first switch element and the fourth switch element areturned on, and the second switch element and the third switch elementare turned off, and

during a period excluding the current output period, the first switchelement and the fourth switch element are turned off, and the secondswitch element and the third switch element are turned on.

(3)

The charge pump circuit according to (1) or (2), further including

a capacitance element including one electrode connected to a signal linebetween the control terminal of the second transistor and the firstswitch element, and another electrode connected to the ground node.

(4)

A charge pump circuit including:

a first transistor including a first terminal, a second terminalconnected to an output terminal, and a control terminal;

a second transistor including a first terminal, a second terminal towhich a constant current is supplied, and a control terminal connectedto the second terminal;

a third transistor including a first terminal connected to the firstterminal of the first transistor, a second terminal connected to avoltage source that supplies an arbitrary voltage, and a controlterminal;

a fourth transistor group including N transistors arranged in a cascadeon a first terminal side of the first transistor, where N is an integergreater than or equal to 1, the N transistors all including controlterminals connected to the control terminal of the second transistor;

a fifth transistor group including N transistors arranged in a cascadeon a first terminal side of the second transistor, the N transistors allincluding control terminals connected to the control terminal of thesecond transistor;

a first switch element that electrically connects the control terminalof the first transistor to the control terminal of the secondtransistor;

a second switch element that connects the control terminal of the firsttransistor to a power supply node;

a third switch element that electrically connects the control terminalof the third transistor to the control terminals of the fourthtransistor group and the fifth transistor group; and

a fourth switch element that connects the control terminal of the thirdtransistor to the power supply node, in which

the first transistor has a channel width and a channel length identicalto those of the second transistor,

the third transistor has the channel width and the channel lengthidentical to those of the first transistor and the second transistor,

in the fourth transistor group, each of the transistors has the channelwidth and the channel length identical to those of the secondtransistor, and a first terminal of one of the transistors is connectedto the power supply node, and

in the fifth transistor group, each of the transistors has the channelwidth and the channel length identical to those of the secondtransistor, and a first terminal of one of the transistors is connectedto the power supply node.

(5)

The charge pump circuit according to (4), in which

during a current output period that is a period in which a current isoutput, the first switch element and the fourth switch element areturned on, and the second switch element and the third switch elementare turned off, and

during a period excluding the current output period, the first switchelement and the fourth switch element are turned off, and the secondswitch element and the third switch element are turned on.

(6)

The charge pump circuit according to (4) or (5), further including

a capacitance element including one electrode connected to a signal linebetween the control terminal of the second transistor and the firstswitch element, and another electrode connected to the power supplynode.

(7)

A charge pump circuit including:

a first transistor including a first terminal, a second terminalconnected to an output terminal, and a control terminal;

a second transistor including a first terminal, a second terminal towhich a first constant current is supplied, and a control terminalconnected to the second terminal;

a third transistor including a first terminal connected to the firstterminal of the first transistor, a second terminal connected to a firstvoltage source that supplies a first voltage, and a control terminal;

a fourth transistor group including N transistors arranged in a cascadeon a first terminal side of the first transistor, where N is an integergreater than or equal to 1, the N transistors all including controlterminals connected to the control terminal of the second transistor;

a fifth transistor group including N transistors arranged in a cascadeon a first terminal side of the second transistor, the N transistors allincluding control terminals connected to the control terminal of thesecond transistor;

a first switch element that electrically connects the control terminalof the first transistor to the control terminal of the secondtransistor;

a second switch element that connects the control terminal of the firsttransistor to a ground node;

a third switch element that electrically connects the control terminalof the third transistor to the control terminals of the fourthtransistor group and the fifth transistor group;

a fourth switch element that connects the control terminal of the thirdtransistor to the ground node;

a sixth transistor including a first terminal, a second terminalconnected to the output terminal, and a control terminal;

a seventh transistor including a first terminal, a second terminal towhich a second constant current is supplied, and a control terminalconnected to the second terminal;

an eighth transistor including a first terminal connected to the firstterminal of the sixth transistor, a second terminal connected to asecond voltage source that supplies a second voltage, and a controlterminal;

a ninth transistor group including M transistors arranged in a cascadeon a first terminal side of the sixth transistor, where M is an integergreater than or equal to 1, the M transistors all including controlterminals connected to the control terminal of the seventh transistor;

a tenth transistor group including M transistors arranged in a cascadeon a first terminal side of the seventh transistor, the M transistorsall including control terminals connected to the control terminal of theseventh transistor;

a fifth switch element that electrically connects the control terminalof the sixth transistor to the control terminal of the seventhtransistor;

a sixth switch element that connects the control terminal of the sixthtransistor to a power supply node;

a seventh switch element that electrically connects the control terminalof the eighth transistor to the control terminals of the ninthtransistor group and the tenth transistor group; and

an eighth switch element that connects the control terminal of theeighth transistor to the power supply node, in which

the first transistor has a channel width and a channel length identicalto those of the second transistor,

the third transistor has the channel width and the channel lengthidentical to those of the first transistor and the second transistor,

in the fourth transistor group, each of the transistors has the channelwidth and the channel length identical to those of the secondtransistor, and a first terminal of one of the transistors is connectedto the ground node,

in the fifth transistor group, each of the transistors has the channelwidth and the channel length identical to those of the secondtransistor, and a first terminal of one of the transistors is connectedto the ground node,

the sixth transistor has a channel width and a channel length identicalto those of the seventh transistor,

the eighth transistor has the channel width and the channel lengthidentical to those of the sixth transistor and the seventh transistor,

in the ninth transistor group, each of the transistors has the channelwidth and the channel length identical to those of the seventhtransistor, and a first terminal of one of the transistors is connectedto the power supply node, and

in the tenth transistor group, each of the transistors has the channelwidth and the channel length identical to those of the seventhtransistor, and a first terminal of one of the transistors is connectedto the power supply node.

(8)

The charge pump circuit according to (7), in which

during a first current output period that is a period in which a currentis output when the current is sunk, the first switch element and thefourth switch element are turned on, and the second switch element andthe third switch element are turned off,

during a period excluding the first current output period, the firstswitch element and the fourth switch element are turned off, and thesecond switch element and the third switch element are turned on,

during a second current output period that is a period in which acurrent is output when the current is supplied, the fifth switch elementand the eighth switch element are turned on, and the sixth switchelement and the seventh switch element are turned off, and

during a period excluding the second current output period, the fifthswitch element and the eighth switch element are turned off, and thesixth switch element and the seventh switch element are turned on.

(9)

The charge pump circuit according to (7) or (8), further including:

a first capacitance element including one electrode connected to asignal line between the control terminal of the second transistor andthe first switch element, and another electrode connected to the groundnode; and

a second capacitance element including one electrode connected to asignal line between the control terminal of the seventh transistor andthe fifth switch element, and another electrode connected to the powersupply node.

(10)

The charge pump circuit according to any of (7) to (9), in which

the first transistor, the second transistor, the third transistor, thefourth transistor group, and the fifth transistor group include anN-type MOS transistor,

the sixth transistor, the seventh transistor, the eighth transistor, theninth transistor group, and the tenth transistor group include a P-typeMOS transistor, and

the first terminal includes a source, the second terminal includes adrain, and the control terminal includes a gate.

(11)

A charge pump circuit including:

a current source transistor including a first terminal connected to aground node, a second terminal connected to an output terminal, and acontrol terminal;

a first switch element that connects the control terminal of the currentsource transistor to a first signal line to which a first voltage isapplied;

a second switch element that connects the control terminal of thecurrent source transistor to the ground node;

a capacitance element including one electrode connected to the firstsignal line, and another electrode connectable to a second signal lineto which a second voltage is applied or a third signal line to which adifference voltage between the second voltage and the first voltage isapplied;

a third switch element that connects the other electrode of thecapacitance element to the third signal line; and

a fourth switch element that connects the other electrode of thecapacitance element to the second signal line.

(12)

The charge pump circuit according to (11), in which

during a current output period that is a period in which a current isoutput, the first switch element and the fourth switch element areturned on, and the second switch element and the third switch elementare turned off, and

during a period excluding the current output period, the first switchelement and the fourth switch element are turned off, and the secondswitch element and the third switch element are turned on.

(13)

The charge pump circuit according to (11) or (12), further including

a transistor including a first terminal, and a second terminal and acontrol terminal connected to the second signal line, in which

the difference voltage is applied to the third signal line by supplyinga constant current to a first terminal side of the transistor.

(14)

A charge pump circuit including:

a current source transistor including a first terminal connected to apower supply node, a second terminal connected to an output terminal,and a control terminal;

a first switch element that connects the control terminal of the currentsource transistor to a first signal line to which a difference voltagebetween a power supply voltage and a first voltage is applied;

a second switch element that connects the control terminal of thecurrent source transistor to the power supply node;

a capacitance element including one electrode connected to the firstsignal line, and another electrode connectable to a second signal lineto which a second voltage is applied or a third signal line to which asum voltage of the second voltage and the first voltage is applied;

a third switch element that connects the other electrode of thecapacitance element to the third signal line; and

a fourth switch element that connects the other electrode of thecapacitance element to the second signal line.

(15)

The charge pump circuit according to (14), in which

during a current output period that is a period in which a current isoutput, the first switch element and the fourth switch element areturned on, and the second switch element and the third switch elementare turned off, and

during a period excluding the current output period, the first switchelement and the fourth switch element are turned off, and the secondswitch element and the third switch element are turned on.

(16)

The charge pump circuit according to (14) or (15), further including

a transistor including a first terminal, and a second terminal and acontrol terminal connected to the second signal line, in which

the sum voltage is applied to the third signal line by supplying aconstant current to a first terminal side of the transistor.

(17)

A charge pump circuit including:

a first transistor including a first terminal connected to a groundnode, a second terminal connected to an output terminal, and a controlterminal;

a first switch element that connects the control terminal of the firsttransistor to a first signal line to which a first voltage is applied;

a second switch element that connects the control terminal of the firsttransistor to the ground node;

a first capacitance element including one electrode connected to thefirst signal line, and another electrode connectable to a second signalline to which a second voltage is applied or a third signal line towhich a difference voltage between the second voltage and the firstvoltage is applied;

a third switch element that connects the other electrode of the firstcapacitance element to the third signal line;

a fourth switch element that connects the other electrode of the firstcapacitance element to the second signal line;

a second transistor including a first terminal connected to a powersupply node, a second terminal connected to the output terminal, and acontrol terminal;

a fifth switch element that connects the control terminal of the secondtransistor to a fourth signal line to which a difference voltage betweena power supply voltage and a third voltage is applied;

a sixth switch element that connects the control terminal of the secondtransistor to the power supply node;

a second capacitance element including one electrode connected to thefourth signal line, and another electrode connectable to a fifth signalline to which a fourth voltage is applied or a sixth signal line towhich a sum voltage of the fourth voltage and the third voltage isapplied;

a seventh switch element that connects the other electrode of the secondcapacitance element to the sixth signal line; and

an eighth switch element that connects the other electrode of the secondcapacitance element to the fifth signal line.

(18)

The charge pump circuit according to (17), in which

during a first current output period that is a period in which a currentis output when the current is sunk, the first switch element and thefourth switch element are turned on, and the second switch element andthe third switch element are turned off,

during a period excluding the first current output period, the firstswitch element and the fourth switch element are turned off, and thesecond switch element and the third switch element are turned on,

during a second current output period that is a period in which acurrent is output when the current is supplied, the fifth switch elementand the eighth switch element are turned on, and the sixth switchelement and the seventh switch element are turned off, and

during a period excluding the second current output period, the fifthswitch element and the eighth switch element are turned off, and thesixth switch element and the seventh switch element are turned on.

(19)

The charge pump circuit according to (17) or (18), further including:

a third transistor including a first terminal, and a second terminal anda control terminal connected to the second signal line; and

a fourth transistor including a first terminal, and a second terminaland a control terminal connected to the fifth signal line, in which

the difference voltage is applied to the third signal line by supplyinga first constant current to a first terminal side of the thirdtransistor, and

the sum voltage is applied to the sixth signal line by supplying asecond constant current to a first terminal side of the fourthtransistor.

(20)

The charge pump circuit according to (19), in which

the first transistor includes an N-type MOS transistor,

the second transistor includes a P-type MOS transistor,

the third transistor includes an N-type MOS transistor,

the fourth transistor includes a P-type MOS transistor, and

the first terminal includes a source, the second terminal includes adrain, and the control terminal includes a gate.

REFERENCE SIGNS LIST

-   1 Electronic circuit system-   10 Control circuit-   100, 100A, 100B, 100C Charge pump circuit-   111 Constant current circuit-   112 Output terminal-   121 Constant current circuit-   122 Output terminal-   131, 132 Constant current circuit-   133 Output terminal-   200, 200A, 200B, 200C Charge pump circuit-   211 Output terminal-   212, 213 Input terminal-   221 Output terminal-   222, 223 Input terminal-   231 Output terminal-   232 to 234 Input terminal-   300, 300A, 300B, 300C Charge pump circuit-   311 Output terminal-   312, 313 Constant current circuit-   321 Output terminal-   322, 323 Constant current circuit-   331 Output terminal-   332 to 335 Constant current circuit-   C11 Capacitance-   SW11 to SW14 Switch-   TR11, TR12, TR13, TR14-1 to TR14-N, TR15-1 to TR15-N Transistor-   C21 Capacitance-   SW21 to SW24 Switch-   TR21, TR22, TR23, TR24-1 to TR24-N, TR25-1 to TR25-N Transistor-   C31, C32 Capacitance-   SW31 to SW38 Switch-   TR31, TR32, TR33, TR34-1 to TR34-N, TR35-1 to TR35-N,-   TR36, TR37, TR38, TR39-1 to TR39-M, TR310-1 to TR310-M Transistor-   C41 Capacitance-   L41 to L43 Signal line-   SW41 to SW44 Switch-   TR41 Current source transistor-   C51 Capacitance-   L51 to L53 Signal line-   SW51 to SW54 Switch-   TR51 Current source transistor-   C61, C62 Capacitance-   L61 to L66 Signal line-   SW61 to SW68 Switch-   TR61, TR62 Current source transistor-   C71 Capacitance-   L71 to L73 Signal line-   SW71 to SW74 Switch-   TR71 Current source transistor-   TR72, TR73 Transistor-   C81 Capacitance-   L81 to L83 Signal line-   SW81 to SW84 Switch-   TR81 Current source transistor-   TR82, TR83 Transistor-   C91, C92 Capacitance-   L91 to L96 Signal line-   SW91 to SW98 Switch-   TR91, TR94 Current source transistor-   TR92, TR93, TR95, TR96 Current source transistor

1. A charge pump circuit comprising: a first transistor including afirst terminal, a second terminal connected to an output terminal, and acontrol terminal; a second transistor including a first terminal, asecond terminal to which a constant current is supplied, and a controlterminal connected to the second terminal; a third transistor includinga first terminal connected to the first terminal of the firsttransistor, a second terminal connected to a voltage source thatsupplies an arbitrary voltage, and a control terminal; a fourthtransistor group including N transistors arranged in a cascade on afirst terminal side of the first transistor, where N is an integergreater than or equal to 1, the N transistors all including controlterminals connected to the control terminal of the second transistor; afifth transistor group including N transistors arranged in a cascade ona first terminal side of the second transistor, the N transistors allincluding control terminals connected to the control terminal of thesecond transistor; a first switch element that electrically connects thecontrol terminal of the first transistor to the control terminal of thesecond transistor; a second switch element that connects the controlterminal of the first transistor to a ground node; a third switchelement that electrically connects the control terminal of the thirdtransistor to the control terminals of the fourth transistor group andthe fifth transistor group; and a fourth switch element that connectsthe control terminal of the third transistor to the ground node, whereinthe first transistor has a channel width and a channel length identicalto those of the second transistor, the third transistor has the channelwidth and the channel length identical to those of the first transistorand the second transistor, in the fourth transistor group, each of thetransistors has the channel width and the channel length identical tothose of the second transistor, and a first terminal of one of thetransistors is connected to the ground node, and in the fifth transistorgroup, each of the transistors has the channel width and the channellength identical to those of the second transistor, and a first terminalof one of the transistors is connected to the ground node.
 2. The chargepump circuit according to claim 1, wherein during a current outputperiod that is a period in which a current is output, the first switchelement and the fourth switch element are turned on, and the secondswitch element and the third switch element are turned off, and during aperiod excluding the current output period, the first switch element andthe fourth switch element are turned off, and the second switch elementand the third switch element are turned on.
 3. The charge pump circuitaccording to claim 1, further comprising a capacitance element includingone electrode connected to a signal line between the control terminal ofthe second transistor and the first switch element, and anotherelectrode connected to the ground node.
 4. A charge pump circuitcomprising: a first transistor including a first terminal, a secondterminal connected to an output terminal, and a control terminal; asecond transistor including a first terminal, a second terminal to whicha constant current is supplied, and a control terminal connected to thesecond terminal; a third transistor including a first terminal connectedto the first terminal of the first transistor, a second terminalconnected to a voltage source that supplies an arbitrary voltage, and acontrol terminal; a fourth transistor group including N transistorsarranged in a cascade on a first terminal side of the first transistor,where N is an integer greater than or equal to 1, the N transistors allincluding control terminals connected to the control terminal of thesecond transistor; a fifth transistor group including N transistorsarranged in a cascade on a first terminal side of the second transistor,the N transistors all including control terminals connected to thecontrol terminal of the second transistor; a first switch element thatelectrically connects the control terminal of the first transistor tothe control terminal of the second transistor; a second switch elementthat connects the control terminal of the first transistor to a powersupply node; a third switch element that electrically connects thecontrol terminal of the third transistor to the control terminals of thefourth transistor group and the fifth transistor group; and a fourthswitch element that connects the control terminal of the thirdtransistor to the power supply node, wherein the first transistor has achannel width and a channel length identical to those of the secondtransistor, the third transistor has the channel width and the channellength identical to those of the first transistor and the secondtransistor, in the fourth transistor group, each of the transistors hasthe channel width and the channel length identical to those of thesecond transistor, and a first terminal of one of the transistors isconnected to the power supply node, and in the fifth transistor group,each of the transistors has the channel width and the channel lengthidentical to those of the second transistor, and a first terminal of oneof the transistors is connected to the power supply node.
 5. The chargepump circuit according to claim 4, wherein during a current outputperiod that is a period in which a current is output, the first switchelement and the fourth switch element are turned on, and the secondswitch element and the third switch element are turned off, and during aperiod excluding the current output period, the first switch element andthe fourth switch element are turned off, and the second switch elementand the third switch element are turned on.
 6. The charge pump circuitaccording to claim 4, further comprising a capacitance element includingone electrode connected to a signal line between the control terminal ofthe second transistor and the first switch element, and anotherelectrode connected to the power supply node.
 7. A charge pump circuitcomprising: a first transistor including a first terminal, a secondterminal connected to an output terminal, and a control terminal; asecond transistor including a first terminal, a second terminal to whicha first constant current is supplied, and a control terminal connectedto the second terminal; a third transistor including a first terminalconnected to the first terminal of the first transistor, a secondterminal connected to a first voltage source that supplies a firstvoltage, and a control terminal; a fourth transistor group including Ntransistors arranged in a cascade on a first terminal side of the firsttransistor, where N is an integer greater than or equal to 1, the Ntransistors all including control terminals connected to the controlterminal of the second transistor; a fifth transistor group including Ntransistors arranged in a cascade on a first terminal side of the secondtransistor, the N transistors all including control terminals connectedto the control terminal of the second transistor; a first switch elementthat electrically connects the control terminal of the first transistorto the control terminal of the second transistor; a second switchelement that connects the control terminal of the first transistor to aground node; a third switch element that electrically connects thecontrol terminal of the third transistor to the control terminals of thefourth transistor group and the fifth transistor group; a fourth switchelement that connects the control terminal of the third transistor tothe ground node; a sixth transistor including a first terminal, a secondterminal connected to the output terminal, and a control terminal; aseventh transistor including a first terminal, a second terminal towhich a second constant current is supplied, and a control terminalconnected to the second terminal; an eighth transistor including a firstterminal connected to the first terminal of the sixth transistor, asecond terminal connected to a second voltage source that supplies asecond voltage, and a control terminal; a ninth transistor groupincluding M transistors arranged in a cascade on a first terminal sideof the sixth transistor, where M is an integer greater than or equal to1, the M transistors all including control terminals connected to thecontrol terminal of the seventh transistor; a tenth transistor groupincluding M transistors arranged in a cascade on a first terminal sideof the seventh transistor, the M transistors all including controlterminals connected to the control terminal of the seventh transistor; afifth switch element that electrically connects the control terminal ofthe sixth transistor to the control terminal of the seventh transistor;a sixth switch element that connects the control terminal of the sixthtransistor to a power supply node; a seventh switch element thatelectrically connects the control terminal of the eighth transistor tothe control terminals of the ninth transistor group and the tenthtransistor group; and an eighth switch element that connects the controlterminal of the eighth transistor to the power supply node, wherein thefirst transistor has a channel width and a channel length identical tothose of the second transistor, the third transistor has the channelwidth and the channel length identical to those of the first transistorand the second transistor, in the fourth transistor group, each of thetransistors has the channel width and the channel length identical tothose of the second transistor, and a first terminal of one of thetransistors is connected to the ground node, in the fifth transistorgroup, each of the transistors has the channel width and the channellength identical to those of the second transistor, and a first terminalof one of the transistors is connected to the ground node, the sixthtransistor has a channel width and a channel length identical to thoseof the seventh transistor, the eighth transistor has the channel widthand the channel length identical to those of the sixth transistor andthe seventh transistor, in the ninth transistor group, each of thetransistors has the channel width and the channel length identical tothose of the seventh transistor, and a first terminal of one of thetransistors is connected to the power supply node, and in the tenthtransistor group, each of the transistors has the channel width and thechannel length identical to those of the seventh transistor, and a firstterminal of one of the transistors is connected to the power supplynode.
 8. The charge pump circuit according to claim 7, wherein during afirst current output period that is a period in which a current isoutput when the current is sunk, the first switch element and the fourthswitch element are turned on, and the second switch element and thethird switch element are turned off, during a period excluding the firstcurrent output period, the first switch element and the fourth switchelement are turned off, and the second switch element and the thirdswitch element are turned on, during a second current output period thatis a period in which a current is output when the current is supplied,the fifth switch element and the eighth switch element are turned on,and the sixth switch element and the seventh switch element are turnedoff, and during a period excluding the second current output period, thefifth switch element and the eighth switch element are turned off, andthe sixth switch element and the seventh switch element are turned on.9. The charge pump circuit according to claim 7, further comprising: afirst capacitance element including one electrode connected to a signalline between the control terminal of the second transistor and the firstswitch element, and another electrode connected to the ground node; anda second capacitance element including one electrode connected to asignal line between the control terminal of the seventh transistor andthe fifth switch element, and another electrode connected to the powersupply node.
 10. The charge pump circuit according to claim 7, whereinthe first transistor, the second transistor, the third transistor, thefourth transistor group, and the fifth transistor group include anN-type MOS transistor, the sixth transistor, the seventh transistor, theeighth transistor, the ninth transistor group, and the tenth transistorgroup include a P-type MOS transistor, and the first terminal includes asource, the second terminal includes a drain, and the control terminalincludes a gate.
 11. A charge pump circuit comprising: a current sourcetransistor including a first terminal connected to a ground node, asecond terminal connected to an output terminal, and a control terminal;a first switch element that connects the control terminal of the currentsource transistor to a first signal line to which a first voltage isapplied; a second switch element that connects the control terminal ofthe current source transistor to the ground node; a capacitance elementincluding one electrode connected to the first signal line, and anotherelectrode connectable to a second signal line to which a second voltageis applied or a third signal line to which a difference voltage betweenthe second voltage and the first voltage is applied; a third switchelement that connects the other electrode of the capacitance element tothe third signal line; and a fourth switch element that connects theother electrode of the capacitance element to the second signal line.12. The charge pump circuit according to claim 11, wherein during acurrent output period that is a period in which a current is output, thefirst switch element and the fourth switch element are turned on, andthe second switch element and the third switch element are turned off,and during a period excluding the current output period, the firstswitch element and the fourth switch element are turned off, and thesecond switch element and the third switch element are turned on. 13.The charge pump circuit according to claim 11, further comprising atransistor including a first terminal, and a second terminal and acontrol terminal connected to the second signal line, wherein thedifference voltage is applied to the third signal line by supplying aconstant current to a first terminal side of the transistor.
 14. Acharge pump circuit comprising: a current source transistor including afirst terminal connected to a power supply node, a second terminalconnected to an output terminal, and a control terminal; a first switchelement that connects the control terminal of the current sourcetransistor to a first signal line to which a difference voltage betweena power supply voltage and a first voltage is applied; a second switchelement that connects the control terminal of the current sourcetransistor to the power supply node; a capacitance element including oneelectrode connected to the first signal line, and another electrodeconnectable to a second signal line to which a second voltage is appliedor a third signal line to which a sum voltage of the second voltage andthe first voltage is applied; a third switch element that connects theother electrode of the capacitance element to the third signal line; anda fourth switch element that connects the other electrode of thecapacitance element to the second signal line.
 15. The charge pumpcircuit according to claim 14, wherein during a current output periodthat is a period in which a current is output, the first switch elementand the fourth switch element are turned on, and the second switchelement and the third switch element are turned off, and during a periodexcluding the current output period, the first switch element and thefourth switch element are turned off, and the second switch element andthe third switch element are turned on.
 16. The charge pump circuitaccording to claim 14, further comprising a transistor including a firstterminal, and a second terminal and a control terminal connected to thesecond signal line, wherein the sum voltage is applied to the thirdsignal line by supplying a constant current to a first terminal side ofthe transistor.
 17. A charge pump circuit comprising: a first transistorincluding a first terminal connected to a ground node, a second terminalconnected to an output terminal, and a control terminal; a first switchelement that connects the control terminal of the first transistor to afirst signal line to which a first voltage is applied; a second switchelement that connects the control terminal of the first transistor tothe ground node; a first capacitance element including one electrodeconnected to the first signal line, and another electrode connectable toa second signal line to which a second voltage is applied or a thirdsignal line to which a difference voltage between the second voltage andthe first voltage is applied; a third switch element that connects theother electrode of the first capacitance element to the third signalline; a fourth switch element that connects the other electrode of thefirst capacitance element to the second signal line; a second transistorincluding a first terminal connected to a power supply node, a secondterminal connected to the output terminal, and a control terminal; afifth switch element that connects the control terminal of the secondtransistor to a fourth signal line to which a difference voltage betweena power supply voltage and a third voltage is applied; a sixth switchelement that connects the control terminal of the second transistor tothe power supply node; a second capacitance element including oneelectrode connected to the fourth signal line, and another electrodeconnectable to a fifth signal line to which a fourth voltage is appliedor a sixth signal line to which a sum voltage of the fourth voltage andthe third voltage is applied; a seventh switch element that connects theother electrode of the second capacitance element to the sixth signalline; and an eighth switch element that connects the other electrode ofthe second capacitance element to the fifth signal line.
 18. The chargepump circuit according to claim 17, wherein during a first currentoutput period that is a period in which a current is output when thecurrent is sunk, the first switch element and the fourth switch elementare turned on, and the second switch element and the third switchelement are turned off, during a period excluding the first currentoutput period, the first switch element and the fourth switch elementare turned off, and the second switch element and the third switchelement are turned on, during a second current output period that is aperiod in which a current is output when the current is supplied, thefifth switch element and the eighth switch element are turned on, andthe sixth switch element and the seventh switch element are turned off,and during a period excluding the second current output period, thefifth switch element and the eighth switch element are turned off, andthe sixth switch element and the seventh switch element are turned on.19. The charge pump circuit according to claim 17, further comprising: athird transistor including a first terminal, and a second terminal and acontrol terminal connected to the second signal line; and a fourthtransistor including a first terminal, and a second terminal and acontrol terminal connected to the fifth signal line, wherein thedifference voltage is applied to the third signal line by supplying afirst constant current to a first terminal side of the third transistor,and the sum voltage is applied to the sixth signal line by supplying asecond constant current to a first terminal side of the fourthtransistor.
 20. The charge pump circuit according to claim 19, whereinthe first transistor includes an N-type MOS transistor, the secondtransistor includes a P-type MOS transistor, the third transistorincludes an N-type MOS transistor, the fourth transistor includes aP-type MOS transistor, and the first terminal includes a source, thesecond terminal includes a drain, and the control terminal includes agate.